Customer telecommunication interface device having a unique identifier

ABSTRACT

Improved telecommunication apparatus is realized with a structure that is tailored to provide an ID signal to the telecommunication network, which signal uniquely identifies the apparatus. The ID signal can be communicated to the network under control of the apparatus, or polled by the network The apparatus includes a second port through which communication services are provided to a customer, and the ID signal can be sent to that second port as well. The apparatus further includes circuitry for processing signals flowing between the two ports, allowing the characteristics of the signal to change and thereby provide for format conversions, encryption, and other capabilities.

CROSS REFERENCE TO RELATED APPLICATIONS

This is a continuation application of an application bearing the Ser.No. 08/627,661, filed Apr. 4, 1996.

This is a continuation application of an application bearing the Ser.No. 08/627,661, filed Apr. 4, 1996, now U.S. Pat. No. 6,178,167. Relatedsubject matter is disclosed in the following applications filedconcurrently herewith for the inventor of this application and assignedto the same Assignee thereof: U.S. patent application Ser. No.08/627,657, entitled “A Customer Telecommunication Interface Device WithBuilt-In Network Features, now U.S. Pat. No. 5,926,464;” U.S. patentapplication Ser. No. 08/627,659, entitled “Packet Telephone System,still pending;” U.S. patent application Ser. No. 08/627,660, entitled“Method And Apparatus For Automated Provisioning And Billing OfCommunication Services, now U.S. Pat. No. 5,835,580;” and U.S. patentapplication Ser. No. 08/627,658, entitled “A Packet Format ForTelecommunication Instruments,” now U.S. Pat. No. 5,943,319.

BACKGROUND OF THE INVENTION

This relates to telecommunications and, in particular, to telephones andinterface devices that are interposed between a telephone and atelecommunications network.

Present day telecommunication networks comprise switches that offer asubstantial amount of control over the network to provide connectivityand customer features, such as “call waiting”, “caller ID”, etc. Thecustomers are connected to the network at its extremities, most oftenthrough analog lines brought to the homes and offices and connected tosimple telephone instruments. The interaction of customers with thenetwork is generally limited still to signaling with the telephoneinstrument's switch hook and with the dial pad.

It is believed that substantial benefits will accrue to the overallnetwork and to users by imparting more sophisticated network interactioncapabilities to the equipment at the extremities of the network.

SUMMARY OF THE INVENTION

Improved telecommunication apparatus is realized with a structure thatis tailored to provide an ID signal to the telecommunication network,which signal uniquely identifies the apparatus. The ID signal can becommunicated to the network under control of the apparatus, or polled bythe network The apparatus includes a second port through whichcommunication services are provided to a customer, and the ID signal canbe sent to that second port as well. The apparatus further includescircuitry for processing signals flowing between the two ports, allowingthe characteristics of the signal to change and thereby provide forformat conversions, encryption, and other capabilities.

BRIEF DESCRIPTION OF THE DRAWING

FIG. 1 presents a block diagram of apparatus that interacts with atelecommunication network in packet format;

FIG. 2 presents a more detailed block diagram of apparatus thatinteracts with a telecommunication network in packet format;

FIG. 3 describes the format of an ATM packet;

FIG. 4 suggests a control approach for controller 300;

FIGS. 5-6 depict modified block diagrams of apparatus that interact witha telecommunication network in packet format;

FIG. 7 illustrates an embodiment that is microprocessor-centered;

FIG. 8 presents an embodiment where messages are stored in a digitalmemory associated with the apparatus controller; and

FIG. 9 presents an embodiment that is suitable for interaction with acircuit-switched central office.

DETAILED DESCRIPTION

One of the most effective means for providing customers with increasedcontrol over their telecommunication capabilities is to employ acommunication protocol that offers a capable mechanism for communicatingcontrol information between the customer and the network. A digitalcommunication approach, such as ISDN, is one such effective mechanism.

In a co-pending application entitled “Packet Telephone System”, filed oneven date hereof, beang the Serial No. 08/627,659, filed Apr. 4, 1996,and initially, and assigned to the assignee of this application, whichapplication is hereby incorporated by reference, a packet telephonesystem is disclosed where a portion, or perhaps even the entire,telecommunication network (both voice and data) consists of a packetswitching based network with network interface units at the extremes ofthe network. Such a network provides all telecommunication services,including plain telephony service (POTS).

The problem with using packet switching systems for plain telephony isthat various delays are inherent in such systems, and those delays makeit very difficult to have an effective, global, system for voicecommunication.

One of the most demanding requirements of voice communication is roundtrip delay. It has been found experimentally that a conversation becomesstrained, unpleasant and disconcerting when a signal's round trip delayis greater than 300 msec (the number varies with people andcircumstances). It is the round trip delay that is important, ratherthan just the one-way, because conversations typically comprisequestions and statements that call for a response. When a responsearrives late, the conversation is perceived to be unsatisfactory.

The round trip delay of a signal is controlled by a number of factors.First, of course, is the distance between the parties. For example, aconversation roughly half-way around the globe and back (40,000 km) willhave a round trip delay of approximately 200 msec. That leaves only 100msec for the other factors that introduce delay (if one is to not exceed300 msec). Those are coding the speech, decoding the speech, coding theresponse, decoding the response, and the necessary routing of signals.For a coast-to-coast conversation within the contiguous United States,the round trip delay is approximately 60 msec, and that leaves about 240msec for those other delays.

When the signal transmission is in the form of packets, the encodingdelay must include the time necessary to wait for a snippet of thespeech signal to accumulate in order for it to be encoded into a packet,and the decoding time must include the time necessary to ascertain thata complete, error-free, packet has arrived. When speech is sampled at8,000 samples per second, a byte of speech signal is generated every 125μsec. With 4:1 speech compression, that translates to one byte per 0.5msec, and with 8:1 speech compression, that translates to one byte per 1msec.

If packets are generated from a plurality of bytes then, of course,there is a delay associated with the assembling of the packet; and thelonger the packet, the longer the assembly delay. Moreover, there is adelay that is associated with the placements of the assembled packetsonto a time multiplexed channel, and that, on the average, is half thelength of a packet.

Routing of packet signals also incurs delays in the traversal throughswitches. First, because present-day packet switches wait till theentire packet has arrived at a switching node before it is routed towardits destination. Second, in some circumstances two packets may collide(in seeking to use the same transmission resource), and one of thepackets must then be delayed. Assuming that a packet is not held up (onthe average), that the routing delays are small, and that the decodingdelays are small, it still remains that there is a 1 packet's worthdelay in assembling the packet, ½ packet's worth of delay in casting thepacket onto the channel, and 1 packet's worth of delay in receiving anddisassembling the packet. It follows, therefore, that packets for aglobal call should be less than 40 bytes for 8:1 compression, and 80bytes for 4:1 compression. Correspondingly, for transcontinental (US)calls, packets should be less than 96 bytes for 8:1 compression, and 192bytes for 4:1 compression.

From the above it is apparent that carrying natural (duplex)conversations is difficult with a packet switching network, and thatlarge packets—such as used in the Internet—cannot work satisfactorily.Accordingly, it is considered that a telecommunication system whichemploys packets for voice telephony and which can handle internationalcalls, or certainly transcontinental calls, reasonably well shouldemploy packets with no more than 100 bytes (including the header and theinformation portions).

Fortuitously, a packet switching protocol is already available thatemploys short packets. Specifically, the ATM (Asynchronous TransferMode) protocol employs packets with 5 byte headers and 48 byte payloads.Use of the ATM protocol allows time to compress speech signals, time toassemble packets, time to encode and decode, time to route packets, andtime for the actual transmission. Thus, using the 53 packet ATM formatand 8:1 compression, for example, a conversation half-way around theworld will have a round trip somewhat greater than 300 msec, but it willprobably be acceptable to most users. More demanding users can attain ashorter overall delay by reducing the speech compression to 4:1 (andperhaps pay a premium for the improved quality).

As an aside, with a packet size that is in the neighborhood of 50 bytes,the Internet protocol results in a very inefficient utilization of thetransmission medium because the addressing scheme used by Internetcurrently employs a 20 byte header (and there is an effort to increasethe header to 40 bytes). A 50 byte packet, or cell, with a 40 byteheader uses at most 20% of the network's capacity to communicate userinformation, and that certainly is inefficient.

Given a global digital network that is ATM-based, where thecustomer-premises instrument interacts with the network through digitalpackets, many desired features are within reach. Control packets can besent by any customer instrument to any other customer instrument,whether that other customer instrument is in an active conversation ornot, and the two instruments can interact with each other to realizevarious features and controls. That other customer instrument can, infact, be a resource instrument, such as a database. One of the “customerinstruments” may, for example, be the administrator of the entirenetwork; and through control packets that are sent to any othercomponent in the entire network, including all other customerinstruments, the administrator can obtain information about the statusof the network and all of its components.

To summarize the above, the contemplated network as disclosed in theaforementioned and incorporated application offers boundless controlcapabilities to voice communication customers by providing apacket-switching network that employs short packets, and by offering thepacket interface directly to the network interface unit. The followingdisclosure addresses the network interface unit.

FIG. 1 presents one illustrative embodiment of apparatus that is adaptedto co-act directly with the contemplated telecommunication network. Itis a customer-premises piece of equipment. Element 1 in FIG. 1 is ananalog interface module. The term “analog interface module” includesmodules that output sound in response to electrical. signals and convertreceived sound to electrical signals, as well as modules that merelyprovide an analog interface to the customer. For example, the analogmodule may include the telephone's circuitry (handset, dial pad, etc.).It may also be merely the conventional telephone jack into which aconventional telephone or the like is plugged. I call such a port a POTSinterface.

Analog interface module 1 is coupled to encoding/decoding module 2 whichprovides a mapping between the analog signal at the interface betweenelements 1 and 2, and the digital signal at the interface betweenelements 2 and 3. The encoding/decoding module encodes the signal thatflows from element 1 to element 3, and decodes the signal that flowsfrom element 3 to element 1.

Element 3 is a data interface module. It converts digital signals fromelement 2 and control signals from element 5 into packets (e.g., ATMpackets), and conversely, it converts packets from element 4 intodigital control signals and digital information signals for elements 5and 3, respectively. Element 4 is a channel interface module. Itsfunction is to provide the necessary translation, or formatting, of thepacket information for the particular channel that is coupled to port200. Lastly, element 5 is the control module, and it communicates withelements 1-4, as described more fully below.

It is important to note that the particular embodiment of elements 1-5is not at all limited to specific hardware modules that are presentlyrealizable. Whereas the following disclosure presents an illustrativeembodiment, it should be kept in mind that any modules, known now or inthe future, that achieve the functions described above, wheninterconnected as depicted in FIG. 1, are within the contemplation ofthis disclosure. This includes equivalents, such as optical modulesrather than the electronic modules described herein, such as includingA/D-D/A conversion means in element 1, or alternately in element 2, etc.A number of such embodiments are illustratively disclosed below.

Consonant with this spirit, FIG. 2 presents a block diagram of apparatusthat effects the functionality of the FIG. 1 diagram (although, for sakeof clarity, it omits showing the control exercised by controller 300over the other elements). In accordance with FIG. 2, a conventionaltelephone is connected at port 100, and the telecommunication network iscoupled to port 200. The information signal at port 100 is analog, andthe control signals comprise the switch hook action and either DTMF(dual-tone multi-frequency) signals or rotary dial signals. As suggestedabove, the circuitry of the telephone connected to port 100 can beincorporated within block 10, leaving port 100 to be the acousticalinterface between the FIG. 1 apparatus and the user. For expositorypurposes, however, it is simpler to assume that a conventional telephoneis connected to port 100. It may also be noted that the FIG. 2 apparatusforms a buffer between the telephone instrument and the network. Assuch, the buffer can be easily used to allow rotary phones to controlthe network as phones with DTMF signals can do today.

In embodiments where port 100 is adapted to be connected to aconventional telephone, block 10 is a central office emulator circuit.It provides DC power to the telephone, it senses hook switch actions,and it decodes DTMF (or rotary dial's time pulse) signals. The controlsignals that are applied by the customer's telephone to port 100 anddetected by block 10 are applied to controller 300 for its consideration(line 101). Alternatively, the actual detection and interpretation ofDTMF signals can be performed by the controller directly (by couplingcontroller 300 to port 100 directly). One embodiment of a central officeemulator circuit is described, for example, in U.S. Pat. No. 4,775,997issued Oct. 4, 1988.

The voice signals that are applied by customer equipment to port 100 arecoupled by emulator 10 to echo canceling circuit 20. Circuit 20 couplesthis incoming signal to encoder 30, and encoder 30 applies the signal toencryption circuit 60 (via multiplexer 31). The output signal ofencryption circuit is coupled to data interface circuit 80, and circuit80 applies its output signal to channel interface circuit 90. Circuit 90applies its output signals to port 200 and, thence, to a transmissionmedium.

Signals arriving at port 200 from the transmission medium are coupled bycircuit 90 to decryption circuit 70 and thence to data interface circuit80. Circuit 70 might be the complement of circuit 60. Informationsignals developed in circuit 70 are applied to decoder 40, and thence toadder 41. Adder 41 combines the signals of decoder 40 with signals fromsynthesizer 50 and applies its output signal to echo canceling circuit20. Following circuit 20, the signal of adder 41 is coupled to emulator10 and, from there, to port 100. Control signals extracted from arrivingpackets by circuit 80 are applied to controller 300 via line 301.

When the processing carried out by the elements to the left of element20 is digital, element 20 must include a A/D converter in the pathbetween element 10 and element 30, and a D/A converter in the pathbetween element 41 and element 10. The signals at port 100 arebidirectional, and so are the signals at the output of emulator 10. Thisis sometimes called “two-wire transmission”. Encoding and decoding, onthe other hand, is best done with unidirectional signals, so circuit 20must include a two-wire to four-wire conversion means. Conversion fromtwo-wire to four-wire format can introduce echo, which corresponds to aleakage of some signal from line 27 into the path that leads to encoder30. Hence, echo canceling should be provided for. The function ofelement 20 is to convert from two-wire to four-wire transmission, tocarry out echo canceling as necessary, and to perform the appropriateA/D and D/A conversions. Its construction is perfectly conventional.

As an aside, the echo canceling in element 20 is not quite the same asin modems. In modems, the effort is to eliminate echo in the analog,two-wire, side. Here, the effort is to eliminate echo in the four-wire,digital, side. An echo canceler roughly of the type recommended for theFIG. 2 apparatus is disclosed in U.S. Pat. No. 5,406,583, issued Apr.11, 1995.

It is expected that encoder 30 will perform speech compression, in thesense of developing a digital representation of the speech signals thatrequires fewer bits than the digital representation at the input toencoder 30. Decoder 40 complements encoder 30. More specifically, when aconversation is carried out between two parties and each party employsan associated network interface unit, the decoder 40 of one unit mustcomplement the encoder 30 of the other unit, and vice versa. When thetwo encoders are the same, then the decoder of a network interface unitis, of course, the complement of the encoder of the same networkinterface unit.

For purposes of this disclosure, any conventional encoding and decodingapparatus can be used to realize encoder 30 and decoder 40. One exampleof encoding/decoding apparatus is presented in U.S. patent applicationSer. No. 07/782,686, titled “Generalized Analysis-by-Synthesis SpeechCoding Method And Apparatus,” filed for W. B. Kleijn on Oct. 25, 1991.The Kleijn application does not show the additional compression that canbe achieved when silence detection is included, but such additionalcompression is described, however, in the ETSI Standard “EuropeanDigital Cellular Telecommunications System Fullrate Speech ProcessingFunctions,” GSM 6.01, and references GSM 6.31, 6.32, and 6.12, May 1994.When 8:1 compression is desired, it may be necessary to take advantageof silence detection.

Adder 41 provides a means for sending audible signals from controller300, via synthesizer 50, to port 100; and multiplexer 31 provides amechanism for sending audible signals from controller 300 to the port200.

Encrypter 60 and decrypter 70 are optional privacy means. The need forencryption is related, of course, to the desire to keep thecommunications from being compromised and to the level of risk that thecommunications channel is insecure. The latter is highly dependent onthe nature of transmission channel created in the transmission mediumconnected to port 200. When that channel is dedicated, in the sense thatother users that are connected to the transmission medium are not privyto the conversation (i.e., cannot tune their equipment to gain access tothe packets appearing at port 200), then encryption is not as necessary.If, on the other hand, when packets sent to port 200 can be captured byany equipment that is coupled to the transmission medium to which port200 is coupled then, of course, encryption is much more desirablebecause the situation opens the opportunity to fraud, in addition to thecompromising of privacy.

Elements 60 and 70 can be very sophisticated, or quite simple. Manyencryption techniques are known in the art, and any one of them can beemployed, as agreed to by the designers of the FIG. 1 apparatus and thedesigners of the network. By way of example, the well-known public keyencryption approach may be used, where the unit sends to the network itspublic key that corresponds to a private key which is embedded orinstalled in element 60, and receives from the network a public key thatthe network assigns to the particular network interface unit. In publickey systems, the party holding the public key can decypher messages froma sender that employs the corresponding private key, but cannot createmessages that would be decyphered by that public key. Also, the partyholding the public key can encode a message to the party holding theprivate key, but no other party can read that message.

The above describes the encryption approach to be agreed to between theFIG. 1 apparatus and the network. That assumes, of course, that thenetwork decyphers the information. Another viable approach is for thenetwork to be completely oblivious to the messages, and the encryptionapproach being agreed to between the network interface units on the twoends of a call.

In any event, since the specific approach that may be used is not withinthe scope of this invention, it is not described any further herein. Itis expected, however, that in applications where encryption is notperceived to be absolutely necessary but elements 60 and 70 arephysically included in the system, those elements will be activated ordeactivated under direction of controller 300, either in response tocontrol signals arriving from port 100, or control signals arriving fromport 200. When deactivated, those elements are “transparent”.

Synthesizer 50 provides a means for creating audible signals to beapplied to port 100. The audible signals comprise the tone signals thattypically come from a central office, such as “dial tone”, “ringing”,and “ring-back” signals. Alerts by means of other tones, pre-recordedspeech, or synthesized speech are also possible, of course,

Data interface block 80 assembles the data provided by element 60 andcontrol signals provided by controller 300 (via path 302) into ATM cellsand, conversely, dissembles decrypted ATM cells and develops controlsignals for controller 300 (path 301) and data signals for element 40.The structure of data interface block 80 can follow the teachings ofU.S. Pat. No. 5,136,584, issued to Hedlung on Aug. 4, 1992.

Channel interface element 90 is also a two-wire to four-wire converterwhenever the channel at port 200 is a “two-wire” system. Primarily,however, element 90 forms the interface to the transmission medium andthe network connected thereto. The transmission medium can be any one ofa variety of types. It can be a wire pair, optical fiber, coax cable (ofthe type used by cable TV companies), power lines, wireless, etc., andthe signal characteristics might be different for the different types ofinterfaces. (The wireless connection can be to a point outside the homeor, for example, to a unit that couples element 90 to a television cableinside the home.) Accordingly, element 90 is designed for the particulartype of transmission medium that the customer has. For all of theabove-mentioned types, however, the digital data is typically convertedto analog form and band-limited to a particular frequency band (perhapsrequiring frequency shifting). This is basically modem technology, andone such approach is described, for example, in “51,84 b/s 16-CAP ATMLAN Standard”, IEEE Journal on Selected Areas in Communications, Vol.13, No. 4, May, 1995, pp. 620-632, authored by G. H. Im, D. D. Harmon,G. Huang, A. V. Mandzik, N.-H. Nguyen, and J.-J. Werner. For opticalfiber interfaces, element 90 includes electrical/optical conversionmeans, and for wireless interfaces, element 90 includes wirelesstransmission and reception means. These are perfectly conventional.

Controller 300 is, conveniently, a microprocessor which controls all ofthe other elements in the FIG. 2 arrangement. Exactly what it does isdependent on the manner by which the FIG. 2 arrangement provides thePOTS service, and the other features that are provided to the customer.Storage element 320 maintains the programs and data that controller 300needs.

The remaining element depicted in FIG. 2 is ID block 310. Block 310stores a unique identifier for each and every constructed piece ofequipment that embodies the FIG. 2 arrangement. It uniquely identifiesthe hardware. As depicted in FIG. 2, it is coupled to controller 300,and through controller 300 a signal that corresponds to the identifieris sent to port 200 (and may also be sent to element 10 and port 100, ifthe need arises). Element 310 can be a ROM chip, burned-in logic valuesin a register, or the like. Element 310 can also be part of thecontroller. The ID identifier signal may be sent to port 200 followingthe initial coupling of the FIG. 2 apparatus to the network, to registerwith the network the fact that the equipment is now part of the network,and at other times, such as described below. As an aside, another uniqueidentifier can be part of the telephone apparatus that is connected toport 100 and, similarly, a unique identifier can be part of allequipment that makes up the network to which port 200 is coupled.

While the above indicates that the identifier of block 310 is unique, itshould be understood that the uniqueness need not be more extensive thanis necessary for a unique identification of the hardware when it isconnected to the telecommunication network. Hence, if the network issubdivided into subsets, or subnetworks, then the ID must be uniquevis-à-vis the other hardware in the particular network, subset, orsubnetwork.

In order to better understand the operation of the FIG. 2 arrangement,and in particular the operation of block 80, it is useful to review thestructure and “components” of the ATM packet, as depicted in FIG. 3.

The first four bits comprise a generic flow control. This field haslocal significance only and can be used to provide standardized locationfunction on the customer's site.

The next byte provides the virtual path identifier (VPI) and thefollowing two bytes correspond to the virtual channel identifier (VCI).

The next three bits correspond to the payload type (PT), which identifywhether the packet contains user information or control information. Itis also used to indicate a network congestion state, or for networkresource management.

The last bit in the fourth byte is the CLP field, which allows the useror the network to optionally determine whether losing a cell ispermitted under certain network traffic conditions.

The fifth byte is a header error check byte (HEC).

The next 48 bytes are the packet payload.

Thus, through the PT field, ATM offers users the ability to identifypackets as being data packets or control packets; and in the latter, thenature of the control is embedded in the 48 payload bytes.

The function of block 80 is to convert groups of bytes into ATM cellsand, conversely, to convert ATM cells into groups of bytes. In the FIG.2 embodiment, at least one piece of information is not encrypted in theATM cells that are constructed in element 80 and applied to element 90,and that is the address field. An additional field which might not beencrypted is the PT field; which in the presented embodimentcharacterizes the cell as a cell that contains speech signalinformation, data, or control information. This field can be used as“speech flag” which may be used in the network to which port 200 iscoupled to give priority to speech signals over data and controlsignals. Alternatively, the priority for the speech packets can beestablished when the virtual circuit is set up. In any event, an ATMcell is assembled by combining the address information (and perhaps thePT field value) with the encrypted data provided by element 60. When areceived (decrypted) ATM cell is disassembled by element 80, the addressfield is discarded and the PT field value is used to determine whetherthe “payload” packets should be routed to controller 300 or to decoder40.

FIG. 4 presents a basic flow chart depicting the operation of the FIG. 2controller. When control information arrives, whether from an ATM cellarriving at port 100, or from element 10, controller 300 detects thearrival of the control information, identifies the nature of thecontrol, and acts appropriately. The following describes the operationof the FIG. 2 hardware in response to some of the more common controls.

In operation, when the FIG. 2 apparatus is in a quiescent state, channelinterface 90 can receive a signal, for example, that corresponds to acontrol cell. Element 90 recognizes (through the address field) that thecell is destined to the FIG. 2 apparatus and applies the cell to element70. Element 70 decrypts the payload and applies the data to element 80.Element 80 recognizes that the cell is a control cell and directs thepayload to controller 300. The control can, for example, be a callinitiation cell, which identifies the calling party that wishes toconnect to the FIG. 2 apparatus. Controller 300 knows that port 100 isnot presently active with another conversation (when that is the case),and therefore it acknowledges the invitation to create a connection, byexecuting the following:

1. Derives the calling party's address (from the call initiation cell).

2. Using its own address and the derived calling party's address, sendsa control cell back to the calling party indicating an acknowledgment.More specifically, controller 300 directs element 80 via line 302 toassemble a control cell that is sent back to the calling party, andinforms element 80 of the control data that is to be transmitted vialine 301 and multiplexer 31.

3. Through synthesizer 50, sends an alert (ringing) signal to port 100.

When the telephone that is connected to port 100 goes off hook, element10 detects this condition and informs controller 300 that the customerwent off hook. That condition indicates that voice communication canproceed; whereupon, controller 300 directs element 80 to assemble andsend a control cell to the network and to the calling party to informthem that the call can proceed, and the ringing signal that is appliedby synthesizer 50 to port 100 is turned off.

When the conversation is terminated by the telephone instrument at port100, and element 10 detects the state change from “off hook” conditionto “on hook” condition, a control cell is sent to the calling party,informing it (and the network) that the conversation was terminated,allowing the calling party to send a command to the network to releasethe virtual path that was assigned to the call by the ATM switches inthe network.

When the condition is such that when the telephone connected at port 100is in conversation with some other party when a call initiation cellarrives (and, of course, controller 300 is aware of this), controller300 sends a “busy” control cell to the calling party.

When the telephone at port 100 wishes to place a call, it goes “offhook” and thereby informs controller 300 of its intention. Controller300, in turn, directs synthesizer 50 to output signals that mimic thecentral office dial tone, which informs the customer at port 100 thatthe system is ready for dialing. Dialed digits that subsequently appearat port 100 are detected in element 10 and applied to controller 300.Controller 300, in turn, directs element 80 to assemble an ATM controlcell that informs the network of its desire and provides the networkwith the number of the called party. The network decides on the pathbetween the calling party and the called party, provides the networkswitches with the necessary information, adds the calling party'saddress to the call initiation cell, and forwards the cell to the calledparty. The called party, as described above, returns either anacknowledgment control cell, or a busy control cell.

In response to an acknowledgment cell, controller 300 directssynthesizer 50 to output a “ringback” signal to port 100. This“ringback” continues until a control cell arrives from the called party,indicating that the called party went “off hook”. At such a time, the“ringback” signal is discontinued and the telephone enters theconversation mode. In response to a “busy” cell, controller 300 directssynthesizer 50 to output the “busy” signal to port 100.

The ID of the FIG. 2 apparatus is included in some, or perhaps all, ofthe cells that are sent out by the FIG. 2 apparatus. That can be used toadvantage by the network. For example, the network can poll the FIG. 2apparatus and request thereby that the apparatus identify itself.Alternatively, controller 300 can include a timer that, every so often,causes the controller to output a control cell to port 200 which informsthe network of the identity of the FIG. 2 apparatus. That timer may beactive all the time, or perhaps just during active conversations. Thetimer could also have different cycle times: a very long cycle time whenthe apparatus is inactive (e.g,. every 4 hours) and a short cycle timewhen the apparatus is active (e.g., every second).

If the polling approach is used, the control cell that initiates thepolling can also request that the apparatus divulge its status, both inthe sense of information that specifies the state of the apparatus, andinformation that informs of the operational viability of the apparatus.Status information of the first kind (operational status) includesinformation such as “idle”, “busy”, “ringing”, “port 100 has nothingconnected to it”, “the telephone at port 100 is off hook”, “encryptionis activated”, etc. Status information of the second kind (viabilitystatus) includes information such as “the encoder is not workingproperly”, “the unit is dead”, “the decrypt circuit found 17 parityerrors since the last check”, etc. In FIG. 2, the status informationthat is collected by controller 300 is depicted by the group of arrows311-313. Of course, a cell that reports to the network on the status ofthe FIG. 2 apparatus includes the ID signal.

The transmission of status information to the network is not limited toresponses to polling queries. As with operational status wherecontroller 300 takes action in response to changes (e.g,. when thetelephone instrument goes off hook), controller 300 can also take actionin response to changes in the viability status information. This cantake the form of a control cell that is sent to the network to informthe network of the problem, an accumulation of data in memory 320, theturning on of an alert indication at the FIG. 2 apparatus to provide avisual alert to the user, or even sending an alert signal to port 100.

The unique ID can also be used in the context of the network. That is,the ID can be the mechanism for tying a user to the use of the networkand to the charges that are billed the user. This function is currentlyhandled by the phone number that is assigned to the user, but in mostsituations the phone number really identifies the network port to whichthe user is connected. By using the ID, the user's apparatus can movefrom location to location, and once the apparatus is connected to thenetwork and registered (e.g., through the above-disclosed pollingprocess), the network can always associate the phone number assigned tothe user with the ID of the user's apparatus and with the network portto which the apparatus is connected.

It should be reiterated, perhaps, that the embodiments disclosed aboveare merely illustrative, and they can be easily extended to coverdifferent capabilities and embodiments that, nevertheless, remain withinthe scope of this invention.

For example, as indicated above, it is quite conceivable that thetelephone instrument coupled to port 100 and element 10 can merge. It isalso quite conceivable that all digital processing—which may include allof the FIG. 2 elements except portions of elements 10 and 90—can beimplemented in one, or a few, stored program processors (see discussionbelow relative to FIG. 7).

Also for example, there is no reason to limit element 10 to a singleport. It is a straight forward extension to include two or more portsout of element 10 to create two independent channels of communication.This is shown in FIG. 5. This simple extension offers customers twoindependent network appearances. Each appearance can correspond to adifferent number, or they both can be known to the network by the samenumber. The network would simply carry two conversations with the twoappearances, with each conversation being identified by an appropriate“conversation flag”. The network would know, for example, that telephonenumber 582-3001 is a network interface unit sitting at a network address333.432 and coupled to port 1 of a network interface unit having the IDAS234094, while telephone number 582-5432 is coupled to port 2 of thesame network interface unit.

A digital appearance can also be had, for example, for a digital faxmachine or another data instrument, and that instrument would be coupledto encoder 30 and adder 41 through a digital interface circuit 15, asshown illustratively in FIG. 6. Element 10 of FIG. 6 and element 15 areadapted, of course, to deal with the conditions that exist when morethan one call flows through element 90 and port 200. In particular, whentwo independent calls are being carried, ATM cells arriving at port 200will have designations that will distinguish the two calls (e.g.,different source addresses, or different virtual circuit labels).Controller 300 is responsive to those designations, and routes thecorresponding packets that are developed by decoder 40 either to port100 or to port 400. This is accomplished by control lines 101 and 102.Correspondingly, information arriving from elements 10 and 15 isaccepted by encoder 30 (the bytes being appropriately staggered bycontroller 300 to avoid collision) and controller 300 keeps track ofthose bytes, and routes them to separate ATM cells that are assembled inelement 80.

The embodiments disclosed above are illustrated with distinct elementsfor the different functions that are implemented. This is, in part, inorder to clearly teach the invention. Other, more compact, embodimentsare possible and, indeed, are likely in view of the trend to implementsystems with microprocessors under control of stored programs. FIG. 7presents such an embodiment, where microprocessor 500 is at the heart ofthe apparatus.

More specifically, FIG. 7 depicts an embodiment where a coaxial cable402 is the transmission medium that couples the telecommunicationnetwork to port 200. Channel interface unit 90 is made up of acombiner/splitter 401, a receiver module 410, and a transmitter module420. The combiner/splitter may be a simple transformer.

Microprocessor 500 is connected to modules 410 and 420. Microprocessor500 supplies module 420 with parameters that the module needs forheaders of ATM packets, and it also supplies the data, or “payload”, ofthe ATM packets. Within module 420, media access unit 421 creates ATMpackets from the information supplied by processor 500. Those packetsare then applied to modulator 422. Modulator 422 converts the bytessupplied by processor 500 to symbols, and modulates a carrier with thosesymbols in accordance with a selected modem approach. In some modulationapproaches, the output of modulator 422 is a baseband analog signal;i.e., occupying a frequency band from 0 to some selected upperfrequency. In such situations, RF transmitter unit 423 which couplesmodulator 422 to combiner/splitter 401 includes an amplifier and amodulator that shifts the band of the signal developed by modulator 422to the band specified for coax cable 402. In the alternative, modulator422 creates a signal that already is in the proper band, and in suchsituations transmitter unit 423 needs to only perform the amplification.

In the reverse direction, the signal arriving at receiver module 410 isan analog signal that carries a large number of information channels;e.g., a number of TV channels. Among them is the information channelthat is aimed at the FIG. 7 apparatus. Accordingly, receiver module 410includes an RF receiver unit 411 that is tuned to receive the correctchannel of information and, if necessary (for the workings of thedemodulator that follows), demodulates the information down to “baseband”. The output of unit 411 is applied to demodulator 412 whichoutputs the ATM packets. Those packets are applied to media access unit413 which reads the stream of bits, interprets it as ATM packets, andwhen it identifies a packet with a header address that corresponds tothe address of the FIG. 7 apparatus, it provides the contents of thatATM packet to processor 500.

The “apparatus address”, by the way, can be the ID of the apparatus,described above, or it can be some other preset identifier, such as a“phone number”. The particular data that is used as an “apparatusaddress” depends, of course, on the network to which the FIG. 7apparatus is connected. In any event, the “apparatus address” can beloaded by microprocessor 500 into a field programmable ROM within unit420.

The encryption and decryption of data signals which, for example, iseffected in the FIG. 2 apparatus with elements 60 and 70, are shown inFIG. 7 with a separate processing unit (430) that is coupled tomicroprocessor 500. It is depicted as a separate unit because withcurrent microprocessor capabilities the encryption and decryptionfunction is too demanding to be accommodated in the same microprocessorthat performs the other functions. Of course, it is quite possible thatfuture microprocessors will be able to handle the load.

Control of microprocessor 500 is effected through stored programs thatreside in memory module 440 that is coupled to microprocessor 500.Memory module 440 is shown to include a ROM portion, a RAM portion, anNVRAM (non-volatile RAM), and a Write Once Memory (WOM) portion. The ROMholds the permanent, basic programs; the RAM holds transitory valuesthat processor 500 determines, or evaluates; and the NVRAM holds thevarious static parameters and programs that are downloaded to theapparatus through port 200. The Write Once Memory may be a fused linktype of memory, and it stores the apparatus ID.

Microprocessor 500 is also connected to CO emulator block 10, describedabove, and block 10 is coupled to port 100. Also, microprocessor 500 isconnected to ethernet circuit 450 which provides an interface betweenmicroprocessor 500 and ethernet port 460 to which digital equipment canbe coupled. This block corresponds to block 15 in FIG. 6.

Thus, microprocessor 500 of FIG. 7 corresponds to controller 300 and allof the other elements shown in FIG. 6, save for the channel interface,CO emulator, the digital interface, and the encrypt and decryptcircuitry.

One advantageous characteristic of the apparatus disclosed above is thatmany features that are now available to home telecommunication systems(e.g., telephone instruments, answering machines, and the like) canoptionally be incorporated in the disclosed apparatus in addition to thebasic POTS features described above. The following presents a number ofexamples:

Messaging

Currently, messaging is either a network-based or customerpremises-based feature (in the form of a telephone answering system, ora PBX-based messaging system). In an arrangement of the type thatemploys the FIG. 2 apparatus, the same capability can be had. Thiscapability can be digital or analog, it can be closely associated withcontroller 300, or it can be a separate conventional telephone answeringmachine that is connected to a second port of element 10. If that secondport is an analog port, the apparatus has a structure that is not unlikethe one presented in FIG. 5. When the telephone answering machine isdigital (in the sense of having a digital interface), then the FIG. 6apparatus is applicable. Lastly, when the telephone answeringfunctionality is incorporated in processor 300, then decoder 40information is fed to processor 300, via line 303, and memory 320 servesas the digital store of incoming messages. This is depicted in FIG. 8.The messaging system's outgoing message is also stored in memory 320 andit is provided to port 200 via line 301. It is stored in memory 320 bycontroller 300 processing a voice message from port 100 via the signalpath from the CO emulator to the controller (e.g., line 101). In analternate embodiment, an additional signal path 304 from encoder 30 tocontroller 300 can be included.

A messaging feature in an arrangement such as shown in FIG. 6 operatesas follows. When a call initiation ATM cell comes into port 200 and isdestined to port 100, controller 300 determines whether port 100 isoccupied with a present conversation or not. When the messaging systemis inactive and when port 100 is busy with another conversation,controller 300 normally sends out a cell that informs the calling partyof the busy status (as has been described above). When port 100 is notbusy, ringing signals are applied to port 100 by synthesizer 50.

When the messaging system is active, the system's operation is altered.Specifically, when port 100 is busy, controller 300 can determine (see“screening” below) whether to direct the call to the telephone answeringport of element 15. When it does, the telephone answering unit isalerted (e.g., by synthesizer 50), is activated, and is caused to recordthe incoming message. When port 100 is not busy but it is determinedthat synthesizer 50 has sent a sufficient number of rings to port 100and port 100 has not gone “off hook”, controller 300 redirects the alertsignal of synthesizer 50 to element 15, and element 15 reacts asdescribed above.

Call Transfer/Forwarding/Bridging

Call transfer, call forwarding, and call bridging are closely related.They basically address the issue of informing the network of what to dowith a present call (call transfer and call bridging) or with a futurecall (call forwarding).

With respect to transfer of present calls, a control signal from theinstrument at port 100 informs controller 300 that a call transfer (forexample) is desired. In response, controller 300 directs element 80 toassemble and send out a control ATM cell that informs the network tomodify the destination address of the call. Once the network gets theinformation, it changes the routing of cells to accommodate the transferrequest.

For bridging, controller 300 can simply accept cells from differentsources and apply the information to port 100, can replicate its speechdata and send out a number of cells, each directed to a differentdestination.

With respect to future calls, i.e., call forwarding, controller 300accepts incoming call initiation cells and, based on data stored by theuser in controller memory 320 which specifies some remote destination,controller 300 directs element 80 to create and send out a control cellthat directs the network to transfer the call to the specified remotedestination. In effect, it is treated as a call transfer process. Ofcourse, it is quite easy to make such call transfers selective, based onthe calling party's ID.

Repertory Dialing

Repertory dialing is merely a mechanism for accessing a pre-storeddialing string. Memory 320 and controller 300 can easily provide thenecessary functionality. Controller 300 can be made sensitive to apredesignated dialing sequence that is reserved for repertory dialing(e.g., a sequence of two digits that starts with “#”) and in responsethereto the controller accesses the appropriate dialing string in memory320.

Caller ID

Caller ID requires a means for informing the user who calling party is.In accordance with the present disclosure, controller 300 has thedestination information of the calling party even before the user goes“off hook”. Therefore, the task of providing a caller ID reduces to thetask of merely providing a translation from the source address of thecalling party to something that is recognized by the customer.

Such translation is achieved for customers who subscribe to the callerID feature by allowing the FIG. 2 apparatus to access a network “CallerID” node (which can be a simple data base that is coupled to the networkthrough a unit that has the FIG. 2 design). When a call initiation cellarrives at port 200, controller 300 effectively establishes a call tothe “Caller ID” node and obtains from that node information about theidentity of the calling party. All this is done before a ringing signalis applied to adder 41 by synthesizer 50. Thereafter, the ringing signalis applied by synthesizer 50, and controller 300 provides the caller IDinformation to the display in the telephone that is connected to port100 (or to a display on the FIG. 2 apparatus itself).

Given the processing and storage capability of the FIG. 2 apparatus, thereceived correlation of calling party information to the caller ID canbe stored in memory 320. Thereafter, translations from the same callingparty can be done locally. This would allow a quicker translation, lessburden on the network, and even a customization of the alert messages(e.g., “your brother Harry is calling”). An interesting alternative tothe telephone display is to tailor the ringing signal to the identity ofthe calling party. This can take the form of distinctive ringing for aclass of callers, or it can even be a synthesis of the caller's name(e.g., “Harry Newman is calling”).

Call Waiting

Call waiting is an arrangement where a party that is busy with oneconversation is informed that another calling party wishes to beconnected. The user can alternate between the two phone calls.

This capability can be easily achieved in the FIG. 2 apparatus becauseit is simply a situation where controller 300 either sends cells to, andaccepts cells from, one destination, or another destination. Controller300, in turn, may be responsive to a switch hook flash, or to some othersignaling means.

Screening

Again, given that controller 300 includes memory, it is possible tostore calling party numbers and designate various call treatments tothose parties. This may include sending calls from selected partiesdirectly to the messaging system, ignoring calls from selected callingparties, etc.

Time-out

There is probably not a person in the US who has not been called duringdinner, or some other inconvenient time. Many of those might appreciatea feature where the telephone ignores all calls (or all calls from otherthan a selected set of calling parties) for a selected period of time.Such a feature can be easily accommodated in controller 300 by combininga timer with the screening feature.

Downloading

The above-described features and capabilities of the disclosed apparatusare service features that are presented for illustrative purposes.Other, or additional, service features can be easily embodied as well.Moreover, it should be understood that whatever set of features isincluded in a particular built apparatus, the set of features need notremain static. That is, features can be removed or added even after theapparatus is built, sold to a user, and installed. Indeed, features canbe added to the apparatus through the connection to the network.

Stated in other words, one of the features that may be included in thedisclosed apparatus is a downloading feature. This feature places a callto a designated number and downloads data into memory 320 (e.g., in FIG.6, or the NVRAM portion of memory 440 in FIG. 7). The manner by whichmicroprocessor 300 interacts with the designated number and downloadsthe data is quite simple, since the only difference between downloadinga program and receiving data that is sent to port 400 (in FIG. 6) isthat the destination of the data is changed; that is, the signal iscaptured by processor 300 via line 303. The concept of downloadingfeatures and capabilities is disclosed in U.S. patent application Ser.No. 08/341,805, filed for B. Waring Partridge on Nov. 18, 1994.Alternatively, of course, a CDROM or floppy disk reader can be coupledto controller 300 (employing well-known approaches for coupling a readerto a computer) and features can be installed through such a reader.

The above descriptions of the network interface units have concentratedon embodiments for a customer-premises unit. It should be realized,however, that the FIG. 5 and FIG. 6 arrangements, slightly modified, areextendible to network interface units that couple the packet-switchednetwork to elements other than customer-premises telephones, answeringmachines, and the like. The network interface unit can couple thepacket-switched network to a PBX, to a central office, and even to awhole other, circuit-switched, network. The differences between the FIG.5 arrangement, for example, and a network interface unit for a centraloffice lie in a) the number of ports 100 that are provided, and b) thenature of the controls that flow between the central office and thenetwork interface unit.

For example, a network interface unit for a central office may include adigital interface 15 for signaling the central office, and a pluralityof echo canceling blocks 20; but it would not have the co-emulatorblocks or the synthesizer block. This is shown in FIG. 9.

There is, of course, also an issue of bandwidth, but that is a mereengineering issue. That is, beyond a certain number of analog trunks tothe central office, elements 30, 60, 70, and 40 will not be able tohandle the computation load. That is solved either with higher clockrates, or with a number of the network interface units being effectivelycombined into one.

I claim:
 1. Customer premises apparatus including a first port forcommunicating with a user and a second port for connecting the apparatusto a packet telecommunications network port at a customer premises, theimprovement comprising: a signal coupler connected between the firstport of said customer premises apparatus and the second port of saidcustomer premises apparatus; and a module that stores a uniqueidentifier that uniquely identifies the apparatus, to distinguish itfrom substantially all other apparatus in said network, and produces anID signal corresponding to the unique identifier, which module iscoupled to the second port to provide the ID signal to the second port.2. The apparatus of claim 1 wherein said first port includes a signalinterface that is suited for connecting a POTS instrument to the firstport.
 3. The apparatus of claim 1 wherein said signal coupler includesmeans for delivering sound to the first port and for converting soundreceived at the first port into an electrical signal.
 4. The apparatusof claim 1 wherein the signal coupler comprises: means for processinginformation signals between the first port and the second port; and acontroller coupled to the means for processing, to the first port, andto the second port, where the controller is responsive to controlsignals from said first port and responsive to control signals from saidsecond port, communicating control signals between said first port andsaid second port.
 5. The apparatus of claim 1 wherein the signal couplerprocesses information signals flowing between the first port and thesecond port; and a controller processes control signals flowing betweenthe first and the second port.
 6. The apparatus of claim 1 wherein saidmodule includes means for coupling said ID signal to the second port. 7.The apparatus of claim 1 wherein said module provides the ID signal tothe second port in response to a control signal applied at the secondport requesting the ID signal.
 8. The apparatus of claim 1 furtherincluding means for effecting the communicating of said ID signal to thesecond port on a repetitive basis.
 9. The apparatus of claim 1 furthercomprising means for reporting operational state of the apparatus to thesecond port.
 10. The apparatus of claim 1 further comprising means forreporting operational state of the apparatus to the second port,together with a communicating of said ID signal to the second port. 11.The apparatus of claim 9 wherein the operational state of the apparatusincludes the operational state of equipment connected to the first port.12. The apparatus of claim 11 wherein said means for reporting operatesin response to a control signal applied to the second port.
 13. Theapparatus of claim 11 wherein said means for reporting operates inresponse to a change in the operational state of the apparatus.
 14. Theapparatus of claim 1 further comprising means for reporting operationalviability of the apparatus to the second port.
 15. The apparatus ofclaim 1 further comprising means for reporting operational viability ofthe apparatus to the second port, together with a communicating of saidID signal to the second port.
 16. The apparatus of claim 14 wherein theoperational viability of the apparatus includes the operationalviability of equipment connected to the first port.
 17. The apparatus ofclaim 16 wherein said means for reporting operates in response to achange in the operational viability of the apparatus.
 18. The apparatusof claim 14 further comprising means for reporting viability status ofthe apparatus to the first port.
 19. The apparatus of claim 4 furthercomprising: a memory coupled to the second port; means in saidcontroller for sending a control signal to the second port, requestingthe transmission to the second port of a software module; and means forstoring in said memory the software module received at the second port.20. The apparatus of claim 1 wherein said signal coupler comprises:means for converting information signals from the first port, arrivingat a first format, to packet signals, where a packet comprises bits thatare devoted to address specification, one or more bits devoted tospecifying whether the packet carries control or information signals,and a bits that are devoted to carrying the control or informationsignals; means for converting packet signals arriving from the secondport into signals having said first format; and a controller forenabling concurrent two-directional flow of signals through said firstport.
 21. The apparatus of claim 20 where the packets are not more than140 bytes long.
 22. The apparatus of claim 20 where the packets are ATMpackets.
 23. The apparatus of claim 1 further comprising: means forsupplying signals to the second port to inform the network that theinformation signals from the first port are voice communication signalsas compared to data signals.
 24. The apparatus of claim 23 wherein themeans for supplying provides a control packet that informs the networkthat the information signals from the first port are voice communicationsignals.
 25. The apparatus of claim 23 wherein the means for supplyingprovides a control packet that informs the network that the informationsignals from the first port are voice communication signals as part ofcontrol packets that the means for supplying sends the network to set upa call from said telephone instrument to a called party connected to thenetwork.
 26. The apparatus of claim 1 wherein said signal couplerincludes a central office emulator that is connected to said first port.27. Customer premises apparatus including a network port for connectionto a telecommunication network, comprising: a signal coupler connectedbetween a first port and a second port, the second port being saidnetwork port; and a module that stores a unique identifier that uniquelyidentifies the apparatus, to distinguish it from substantially all otherapparatus in said network, and produces an ID signal corresponding tothe unique identifier, which module is coupled to provide the ID signalto the first port upon initial coupling to the telecommunicationnetwork.
 28. The apparatus of claim 27 wherein said signal couplercomprises: an echo canceler having an analog signal node coupled to thefirst port and including two digital signal nodes, where one of thedigital signal nodes outputs digital signals and the other of thedigital signal nodes receives digital signals; interface circuitryconnected to the second port; and a digital processor interposed betweenthe interface circuitry and the two digital nodes for coupling signalsbetween the interface circuitry and the echo canceler.
 29. The apparatusof claim 28 where signals between the interface circuitry and thedigital processor are packets that contain a header portion and aninformation portion.
 30. The apparatus of claim 28 wherein signalsflowing between said interface circuitry and the second port are analogsignals.
 31. The apparatus of claim 28 wherein the interface circuitrymodulates digital signals of said second port onto an analog carriersignal.
 32. The apparatus of claim 31 wherein the interface circuitryincludes at said second port wireless transmission means.
 33. Theapparatus of claim 28 the interface circuitry includes means associatedwith said second port for coupling signals flowing through the secondport to a coax cable.
 34. The apparatus of claim 28 wherein theinterface circuitry includes means associated with said second port forcoupling signals flowing through the second port to a optical fibercable.
 35. The apparatus of claim 28 wherein the interface circuitryincludes means associated with said second port for coupling signalsflowing through the second port to a 60 Hz power line.
 36. The apparatusof claim 28 where said first port is adapted for connecting to atelephone instrument.
 37. Customer premises apparatus comprising: afirst electronic port adapted for connection to a user apparatus; asecond port adapted for connection to a packet telecommunicationsnetwork; a signal coupler connected between the first port of saidcustomer premises apparatus and the second port of said customerpremises apparatus; and a module that stores a unique identifier thatuniquely identifies the apparatus, to distinguish it from substantiallyall other apparatus in said packet network, and produces an ID signalcorresponding to the unique identifier, which module is coupled to thesecond port to provide the ID signal to the second port.
 38. Theapparatus of claim 37 wherein said first port is characterized by asignal interface that is suited for connecting a POTS instrument to thefirst port and operating said instrument.